[BMIM]HSO_4离子液体腐蚀性的实验与分子模拟

基于失重法和分子模拟方法,研究了1-丁基-3-甲基咪唑硫酸氢盐([BMIM]HSO_4)的腐蚀性和离子液体分子与金属表面的相互作用。实验结果表明[BMIM]HSO_4对304不锈钢具有腐蚀性,且在水溶液中腐蚀性显著增强。基于量子化学方法计算了[BMIM]HSO_4分子的HOMO和LUMO分布、Fukui指数及分子内部特征参数,计算结果表明[BMIM]HSO_4在Fe金属表面吸附的位置主要集中在阴离子硫酸氢根和阳离子咪唑环上,可分别形成配位键和反馈键,在水溶液中[BMIM]HSO_4分子与金属表面的相互作用变弱。分子动力学模拟揭示了在不同的环境中[BMIM]HSO_4分子在Fe金属表面的吸附过程和吸附能。量子化学计算和分子动力学模拟结果一致,从理论上解释了在水溶液中[BMIM]HSO_4腐蚀性增强的原因。     

离子液体在甲醇/硫酸介质中对Q235钢表面的缓蚀性能

探究硫酸存在时Q235钢在甲醇中的腐蚀行为,以及离子液体1-丁基-3-甲基咪唑氯盐（[Bmim]Cl）对金属表面的缓蚀作用。通过静态失重法、电化学测试、扫描电子显微镜来测定[Bmim]Cl对Q235钢的缓蚀性能。并利用量子化学计算和分子动力学模拟分析[Bmim]Cl分子的缓蚀机理。在甲醇中随着硫酸含量的增加碳钢的腐蚀速率增加。含有59.51 ml 0.05 mol·L^-1 H₂SO₄的甲醇溶液作为腐蚀介质时,随着[Bmim]Cl浓度升高,缓蚀效率逐渐增大,当浓度为0.6 mol·L^-1时,缓蚀效率达到最佳值,为90.63%,且[Bmim]Cl是主要控制阳极反应的混合抑制剂,SEM分析表明在含有缓蚀剂溶液中浸泡后的Q235钢表面相对于未加缓蚀剂更加平整。前线轨道分析和Fukui指数都表明,离子液体在碳钢表面的吸附位点分布在咪唑环上,与Fe发生化学吸附。分子动力学模拟结果表明缓蚀剂分子以阳离子[Bmim]⁺平行吸附于金属表面,阴离子Cl^-扩散在溶液中的方式达到缓蚀的效果。理论计算结果与实验结果一致,即[Bmim]Cl在甲醇/硫酸水溶液中对Q235钢具有很好的缓蚀作用,为新型离子液体缓蚀剂研究应用奠定了基础。     

咪唑类离子液体脱除气体中有机硫化物的研究

以1-丁基-3-甲基咪唑为阳离子制备了[BMIM]Ac、[BMIM]HSO₄、[BMIM]DBP、[BMIM]SCN等4种脱有机硫咪唑类离子液体,通过FT-IR和¹HNMR等表征验证了其分子结构特征,考察了不同咪唑离子液体对硫醇的脱除效果。结果表明,4种离子液体中[BMIM]Ac可与硫醇形成稳定的氢键,表现出较优的脱硫能力,常压下当含硫醇的原料气流量为100 mL/min时,吸收2 min后可脱除83%的甲硫醇和乙硫醇,丙硫醇的脱硫率可达到92%;另外,该离子液体脱硫性能稳定、再生循环性能优异,可推广用于天然气中有机硫的脱除。     

咪唑啉类缓蚀剂性能的评价及其机理研究

针对陕北某天然气气井腐蚀现象日益严重以及天然气中H2S,CO2等酸性组分质量浓度不断增大等一系列亟待解决的生产实际问题,首先利用质量损失法对4种常用的咪唑啉类缓蚀剂进行了缓蚀效果评价,然后通过量子化学计算和分子动力学模拟的方法对其缓蚀行为和作用机理进行了初步研究。结果表明:咪唑啉类缓蚀剂对金属的缓蚀作用,主要由于其分子中的咪唑环及极性基团的作用;发生吸附时,咪唑环优先吸附于金属表面,有利于咪唑啉分子在金属表面形成稳定的保护膜。同时憎水支链的自由移动与伸展,能够在远离金属表面的地方形成一层致密的疏水层,阻碍了腐蚀介质与金属基体的接触,有效地增强了咪唑啉分子的缓蚀效果。缓蚀剂缓蚀性能的理论评价结果与实验结果相吻合。     

离子液体催化氯乙酸甲酯合成氯乙酸-2-庚酯的研究

探索了离子液体催化氯乙酸甲酯和2-庚醇的酯交换反应,制备了1-甲基-3-（丙基-3-磺酸基）咪唑对甲苯磺酸盐[MIM-PS][PTSA]、1-甲基-3-（丙基-3-磺酸基）咪唑硫酸氢盐[MIM-PS][HSO₄]、1-丁基-3-甲基咪唑硫酸氢盐[BMIM]HSO₄、N-甲基咪唑磷酸盐[HMIM]H₂PO₄四种离子液体催化剂并用于酯交换反应,通过考察产品氯乙酸-2-庚酯收率,筛选出最佳催化剂[MIM-PS][PTSA]。并用[MIM-PS][PTSA]考察了反应温度、反应时间、催化剂添加量、催化剂循环使用对合成产品收率的影响。结果表明：将氯乙酸甲酯和2-庚醇在100 ℃下,添加5% [MIM-PS][PTSA]催化剂,反应6 h,合成氯乙酸-2-庚酯,收率可达76.3%,离子液体重复使用3次,氯乙酸-2-庚酯收率仍大于初次收率的95%。本实验用离子液体做溶剂或催化剂,反应条件稳定,可循环利用、对环境友好,且产品收率高,为工艺放大提供实验条件参考。     

6种燕尾形苝二酰亚胺类双子表面活性剂对碱性锌电极缓蚀机理理论研究

为了研究燕尾型苝二酰亚胺类双子表面活性剂对碱性锌电极缓蚀机理,利用密度泛函理论（DFT）和分子动力学模拟（MD）方法,探讨了两类共6种燕尾型苝二酰亚胺类双子表面活性剂的吸附行为。DFT计算结果表明,前线分子轨道分布主要位于分子核心的苝二酰亚胺骨架上,且苝二酰亚胺骨架上的N原子为分子的反应活性中心。分子动力学模拟表明,6种燕尾型苝二酰亚胺类双子表面活性剂均能与水溶液中的金属锌表面发生相互作用,N₂、P₂在两类双子表面活性剂中均表现出有较高的吸附能和较大的扩散系数,吸附能分别为-11315.868 kcal/mol、-10785.698 kcal/mol,扩散系数分别为2.5、1.32;研究结果同时表明,N₂和P₂形成的双子表面活剂膜层对腐蚀粒子OH^-的阻止效果较好,能够在金属锌表面起到很好的缓蚀效果。     

2,5-二芳基-1,3,4-噻二唑衍生物的合成及缓蚀性能

合成4种2,5-二芳基-1,3,4-噻二唑化合物,即2,5-二苯基-1,3,4-噻二唑(DPTD),2,5-二(2-羟基苯)-1,3,4-噻二唑(2-DHPTD),2,5-二(3-羟基苯)-1,3,4-噻二唑(3-DHPTD)和2,5-二(4-羟基苯)-1,3,4-噻二唑(4-DHPTD)。通过Tafel极化曲线和电化学阻抗研究4种油溶型噻二唑衍生物在50 mg·L^-1硫-乙醇体系中的缓蚀性能,电化学测试表明:腐蚀液中添加噻二唑衍生物后,银片腐蚀得到抑制;随着缓蚀剂浓度增大,腐蚀电流密度减小,缓蚀效率增大;当缓蚀剂浓度为90 mg·L^-1时,4种缓蚀剂DPTD、2-DHPTD、3-DHPTD和4-DHPTD的缓蚀效率分别为85.8%、94.6%、96.4%和97.1%。采用扫描电子显微镜和原子力显微镜观察其表面形貌,可知缓蚀剂在金属表面形成一层保护膜,阻止腐蚀物质与金属表面的接触,从而抑制银片腐蚀。经分子动力学分析可知,4种噻二唑衍生物吸附于金属表面遵循Langmuir等温方程,且吸附属于以化学吸附为主的混合型吸附。量子化学计算和分子动力学模拟研究表明,4种缓蚀剂均具有很好的缓蚀作用,且4种缓蚀剂的缓蚀效率大小顺序是[4-DHPDT]> [3-DHPDT]> [2-DHPDT]> [DPDT],这与实验结果一致。     

不同管径碳纳米管中CO2/CH4分离的分子模拟

生物甲烷路线在CO₂减排和节能方面有很大的应用前景。而对生物沼气的分离是此路线的一个关键问题,特别是在60℃和0.1 MPa下。巨正则Monte Carlo（GCMC）和平衡分子动力学（EMD）的分子模拟方法研究CO₂和CH₄在不同管径的碳纳米管（CNT）中的吸附和扩散,可以从分子层面研究生物沼气的分离机理。分别计算了CO₂/CH₄二元混合物吸附量、吸附选择性、自扩散系数和渗透选择性等参数。模拟结果表明：由于碳管的受限空间和CO₂与碳纳米管壁面分子之间强相互作用,导致二元等物质的量的混合物CO₂/CH₄的吸附量和扩散系数的差异。CO₂的吸附量和自扩散系数都比CH₄的大。渗透选择性在碳管管径达到最接近1 nm时达到最大值,此时混合物的分离过程是吸附控制,而非扩散控制。     

苯乙醇和茴香醚在含Fe蚕沙基生物碳材料的储香与释放性能研究

选用桑蚕废弃物蚕沙为碳源,利用ZnCl₂和FeCl₂作为活化剂,通过一步合成法获得一种Fe掺杂高石墨化多孔生物炭材料Fe/Z-ASE,并测定香精化合物分子苯乙醇和茴香醚在Fe/Z-ASE上的吸附和缓释动力学行为,然后再通过量子化学计算分析苯乙醇、茴香醚与Fe/Z-ASE的作用关系以及苯乙醇、茴香醚分子间作用力。结果发现：蚕沙多孔炭Fe/Z-ASE孔隙结构发达,表面石墨化碳含量高,Fe元素分布均匀,其BET比表面积为950.9 m²/g且中孔占60%以上,是一种表面疏水并呈现弱极性的多级孔生物炭材料;在苯乙醇和茴香醚的扩散和控释过程中,茴香醚具有比苯乙醇更高的吸附量（510 mg/g）和扩散动力学常数（1.7×10^-2 min^-1）,而且在不同初始茴香醚吸附量下（150~500 mg/g）其都能获得较好的控释效果。随后通过密度泛函DFT模拟计算可知,茴香醚和苯乙醇都是弱碱,能与Fe/Z-ASE材料上的弱酸性吸附位（Fe-C）产生相互作用,而且由于茴香醚的碱性更弱,所以与Fe/Z-ASE的作用力更强。然后再通过分子动力学分析可知,苯乙醇分子间能产生强氢键作用而茴香醚分子间不存在强相互作用,所以苯乙醇分子在高初始吸附量下不易被脱附,而茴香醚分子在高/低初始吸附量下都能获得较高脱附保留率。     

离子液体反应萃取精馏合成乙酸乙酯

采用离子液体1-磺酸丁基-3-甲基咪唑硫酸氢盐([HSO₃bmim][HSO₄])和1-丁基-3-甲基咪唑双三氟甲磺酰亚胺盐([BMIM][Tf₂N])分别作为催化剂和萃取剂,对乙酸甲酯与乙醇合成乙酸乙酯和甲醇的反应萃取精馏(RED)过程进行了模拟计算。在反应动力学和汽液相平衡分析基础上建立了反应萃取精馏流程,研究了理论板数、回流比、持液量、进料位置、溶剂比(萃取剂进料与原料进料摩尔流量的比值)、催化剂进料流量等参数对反应萃取精馏过程的影响。在优化的操作条件下,甲醇纯度为0.9922,乙酸乙酯纯度为0.9905,乙酸甲酯转化率为0.9922。     

NEW ARYLAZODYES AS CORROSION INHIBITORS FOR MILD STEEL IN HCl SOLUTION

Five arylazocyanoacetamide derivatives were investigated as corrosion inhibitors of mild steel in 2 M HCl solution using weight loss and galvanostatic polarization techniques. The inhibiting properties were found to depend on the concentration, the temperature, and the molecular structure of the compounds. Enhancement in inhibition efficiency of these compounds was observed on addition of KSCN due to synergism. The inhibitive action may be attributed to adsorption of inhibitor molecules on the active sites of the metal surface following the Frumkin adsorption isotherm. Thermodynamic parameters for the corrosion of mild steel in the presence and absence of the arylazocyanoacetamide derivatives have been calculated. Polarization curves indicate that these compounds act as mixed-type inhibitors. The correlation between inhibition efficiency and quantum chemical parameters has been investigated by PM3 quantum chemical calculation.     

Molecular simulation, quantum chemical calculations and electrochemical studies for inhibition of mild steel by triazoles

The inhibition performance of three triazole derivatives on mild steel in 1 M HCl were tested by weight loss, potentiodynamic polarization and electrochemical impedance spectroscopy (EIS). The adsorption behavior of these molecules at the Fe surface was studied by the molecular dynamics simulation method and the quantum chemical calculations. Results showed that these compounds inhibit the corrosion of mild steel in 1 M HCl solution significantly. Molecular simulation studies were applied to optimize the adsorption structures of triazole derivatives. The iron/inhibitor/solvent interfaces were simulated and the charges on the inhibitor molecules as well as their structural parameters were calculated in presence of solvent effects. Aminotriazole was the best inhibitor among the three triazole derivatives (triazole, aminotriazole and benzotriazole). The adsorption of the inhibitors on the mild steel surface in the acid solution was found to obey Langmuir's adsorption isotherm.     

Inhibiting Effect of Ionic Liquids on the Corrosion of Mild Steel in H2S and HCl Solution

Four imidazolium-based ionic liquids (ILs) were selected to investigate the inhibiting effect of ILs with various alkyl chain lengths on the corrosion of mild steel in H₂S and HCl solution using electrochemical experiments, weight loss and surface analyses, and quantum chemical study. The results demonstrated that these ILs acted as mixed-type inhibitors and efficiently inhibited the corrosion of mild steel in H₂S and HCl solution. Their excellent corrosion inhibition ability was due to their adsorption process on the metal surface, which followed the Langmuir adsorption isotherm. Furthermore, extending the alkyl chain length in the ILs could improve their inhibition performance.     

Electrochemical and quantum chemical study of purines as corrosion inhibitors for mild steel in 1 M HCl solution

The purines and its derivatives, such as, guanine, adenine, 2,6-diaminopurine, 6-thioguanine and 2,6-dithiopurine, were investigated as corrosion inhibitors for mild steel in 1 M HCl solution by weight loss measurements, electrochemical tests and quantum chemical calculations. The polarization curves of mild steel in the hydrochloric acid solutions of the purines showed that both cathodic and anodic processes of steel corrosion were suppressed. The Nyquist plots of impedance expressed mainly as a depressed capacitive loop with different compounds and concentrations. For all these purines, the inhibition efficiency increased by increasing the inhibitor concentration, and the inhibition efficiency orders are 2,6-dithiopurine > 6-thioguanine > 2,6-diaminopurine > adenine > guanine with the highest inhibiting efficiency of 88.0% for 10⁻³ M 2,6-dithiopurine.The optimized structures of purines, the Mulliken charges, molecular orbital densities and relevant parameters were calculated by quantum chemical calculations. The quantum chemical calculation results inferred that the adsorption belong to physical adsorption, which might arise from the π stacking between the π electron of the purines and the metal surface.     

月桂基咪唑啉对Q235钢的缓蚀吸附作用

采用失重法和电化学方法研究了月桂基咪唑啉（IM-11）、1-氨乙基-2-月桂基咪唑啉（AIM-11）和1-羟乙基-2-月桂基咪唑啉（HIM-11）三种化合物在CO₂饱和的3%NaCl溶液中对Q235钢的缓蚀性能,探讨了其在Q235钢表面的吸附行为。结果显示,3种化合物均具有较好的抗相似文献   

Corrosion inhibition performance of 2-mercaptobenzimidazole and 2-mercaptobenzoxazole compounds for protection of mild steel in hydrochloric acid solution

The effect of some mercapto functional azole compounds on the corrosion of mild steel in 1 M hydrochloric acid solution was studied by polarization and electrochemical impedance spectroscopy (EIS). Polarization studies showed depression of cathodic and anodic polarization curves in the presence of mercapto functional azole compounds, indicating mixed type corrosion inhibition of the compounds. Double layer capacitance and charge transfer resistance values were derived from EIS results. Changes in impedance parameters are indicative of adsorption of these compounds on the metal surface. Surface analysis SEM/EDX showing presence of sulfur on the surface confirmed the adsorption of the azole compounds on the mild steel surface as showed by electrochemical methods. Both compounds contain a pyridine-like nitrogen atom and a sulfur atom in their molecular structure, while they differ in only one heteroatom: oxygen in the oxazole ring and pyrrole-like nitrogen in the imidazole ring. The results of the electrochemical techniques revealed that changing the pyrrole like nitrogen atom to oxygen atom in the azole ring results in a decrease of corrosion inhibition performance in hydrochloric acid solution, which could be related to more negative charge on pyrrole-like nitrogen atom in comparison to oxygen atom as depicted by quantum chemical calculations.     

Red tetrazolium as an effective inhibitor for the corrosion of cold rolled steel in 7.0 mol·L− 1 H2SO4 solution

The corrosion inhibition of cold rolled steel (CRS) in 7.0 mol·L^-1 H₂SO₄ solution by red tetrazolium (RTZ) was carefully investigated using both experimental procedures and theoretical techniques. The results show that RTZ acts as an effective inhibitor for the corrosion of CRS in 7.0 mol·L^-1 H₂SO₄, and the maximum inhibition efficiency is higher than 95% with a RTZ concentration of 2.0 mmol·L^-1. The adsorption of RTZ on CRS surface follows Langmuir isotherm. RTZ effectively retards both cathodic and anodic reactions, and acts as a mixed-type inhibitor. EIS exhibits two capacitive loops, and their resistances increase drastically in the presence of RTZ. SEM and AFM confirm that the addition of RTZ could significantly retard the corrosion of CRS surface. A series of characterizations like FTIR, RS, XRD and XPS reveal that the corrosion CRS surface is composed of the corrosion products of iron sulfates, iron oxides and iron hydroxide, as well as inhibitor. Theoretical results of quantum chemical calculation and molecular dynamics (MD) indicate that the adsorption center of RTZ⁺ (organic cationic part of RTZ) mainly relies on its tetrazole ring, and the adsorption of RTZ⁺ on Fe (001) surface is in a nearly flat orientation mode.     

Theoretical and experimental studies of dried marjoram leaves extract as green inhibitor for corrosion protection of steel substrate in acidic solution

Dried marjoram leaves (DML) aqueous extract solution was prepared and characterized by Fourier transform infrared spectroscopy (FTIR) and cyclic voltammetry (CV). The effect of DML solution concentration on corrosion protection of mild steel in 0.5?M H₂SO₄ at different temperatures was studied using anodic and cathodic polarization and electrochemical impedance spectroscopy (EIS) measurements. It was determined from the polariazation curves that the DML acts as a mixed type inhibitor since, both the cathodic and anodic reactions of mild steel corrosion were inhibited. The protection efficiency increases with increasing concentration of DML and decreasing temperatures. The surface morphology was investigated before and after adsorption of DML molecules on the steel surface using scanning electron microscope (SEM). The activation and adsorption parameters were calculated and discussed. The results were supported using density functional theory (DFT), and the quantum chemical parameters were estimated. These parameters reveal the effect of the electronic structure of Thymol, the main component of DML, on its electron donating ability at the B3LYP/6-311?+?G (d, p) level.